KR100440498B1 - High gain visual system with wide viewing angle - Google Patents

Abstract

The present invention is a video system that is particularly useful for advertising devices

In view of the disadvantage that the conventional imaging system is inversely proportional in brightness and left and right viewing angle, and the brightness of the conventional projector is limited in increasing brightness.

In the present invention, the screen is a spherical screen, but the reflectance of the screen surface is composed of 5-40% of the reflecting surface, and the projector is placed in the focal position of the co-spherical screen, the left and right of the plurality of 2-3 Placed at a square 10-45 degree angle, the projector is composed of a projector with a built-in left and right image distortion correction device

By acquiring 5-40 times higher brightness image and 144 degrees left and right wide field of view, it is possible to display high brightness image in bright places, and it is very useful invention of large image billboard, auditorium image, etc.

Description

Wide View High Brightness Imaging System {HIGH GAIN VISUAL SYSTEM WITH WIDE VIEWING ANGLE}

The present invention provides a high-brightness image system capable of displaying a high-brightness image that is five times brighter than a normal screen image and a wide viewing angle of two or more times wider than the left and right viewing angles.

Conventional projectors can display bright screens only in small screens or dark rooms, but when they are used in bright places or large screens, the brightness is rapidly reduced in proportion to the ambient light or screen size. Could not be used in place.

The LED display structure using the LED has good brightness, but due to the particle size of the LED display, the image is rough, the life of the three primary LEDs are different, and the maintenance cost is excessive.

The brightness of the screen is expressed by the gain factor of the screen's reflection ratio. It is known that ordinary screens usually have 1-2 gains and reflectances of 1-2%.

Increasing the number of gains, the reflectance index, to increase the brightness of the screen, narrows the left and right viewing angles due to the directivity of the screen, and decreasing the reflectance of the screen to increase the left and right viewing angles increases the scattering rate but decreases the brightness.

In other words, the brightness of the screen and the viewing angle are inversely related to each other.

In addition, the technology to increase the brightness of a general projector is to increase the brightness of the light source lamp, which not only involves a lot of heat, but also involves a complicated technical problem such as preventing thermal damage of the liquid crystal image. The price is also twice as expensive.

In addition, two or more projectors can be used on a common screen with one or two gains to increase brightness, but in this case, there is a light increase effect, but the brightness of the light source lamp is not strong. As a result, the image on the screen became slightly brighter, and it did not have a great effect.

For example, a light source of 100 lux brightness was 1% of the brightness of a conventional GAIN screen.

Therefore, when the conventional screen is used in a conventional projector, there is a limit to use it as an advertisement device in public places, department stores, large shopping malls, etc., where multiple people come and go.

According to the present invention, in order to solve the problem that the high reflectance of the screen narrows the viewing angle and the brightness of the screen decreases when the viewing angle is enlarged, the screen having a brightness of 5 to 40 gains is formed in a spherical shape such as a lens and the focal position of the spherical surface of the screen By arranging the projector on the screen, the brightness is increased by 5-40 times, and the projector is composed of two to three times in the right and left quadrangles, and the reflection angle by the rectangular projection and the left and right viewing angles due to the scattering ratio of the screen itself are matched. A wide field of view with high brightness, especially useful for advertising equipment, can be realized because it realizes a wide field of view that has been magnified by 2 to 4 times more than before, and corrects image distortion due to the square projection of the projector to realize a high brightness image in a bright place. In presenting how to build.

1 is an explanatory diagram of an embodiment of the present invention;

2 is a diagram illustrating the operation of a general screen

3 is an explanatory view of the screen operation of the present invention;

4 is a diagram illustrating the configuration and operation of the present invention.

5 is an operation explanatory diagram related to an embodiment of the configuration of the present invention;

6 is an explanatory view of the viewing angle division of the present invention;

Figure 7 is a diagram illustrating the distortion of the screen during the projection of the present invention

8 is an explanatory diagram of an upper and lower screen distortion correction system.

9 is an explanatory diagram of a left and right screen distortion correction system.

10 is an explanatory diagram of distortion correction when matching left and right images

11 is an explanatory diagram of a multi-screen audio-visual angle

Brief description of the designations for the symbols in the drawings

Screen 2.3.4. Projector 5.6 support

A. Left field of view B. Center field of view C. Right field of view

R. Spherical Curvature of the Screen F. Focus Position of Spherical Curvature of the Screen

P. Surface Reflectance of the Screen

As shown in Fig. 1, the present invention comprises a projector 2, 3 having a screen 1 and a distorted image correcting apparatus therein, and supports 5, 6 supporting the same. It is a technical term used in optics, which refers to defects that arise because magnification changes with distance from the axis, rather than aberration that comes from poor sharpness.

4 and 5, the screen of the present invention is constructed as follows.

The shape of the screen is composed of a spherical shape by spherical curvature, and the positions of the projectors 2 and 3 are arranged at the focal position of the spherical surface of the copper screen 1.

That is, the image projected on the general screen of 1 gain as shown in Fig. 2 is scattered in all directions, so even though it is dark, the image is uniformly displayed even though it is dark. At high reflectivity of more than%, the projector reflects at angle B, which is the same angle as the angle of incidence A entering the screen 10 from the projector. In this case, the viewer sees only a part of the image, which is the inverse angle G range formed by B. You will not be able to function.

Accordingly, as shown in FIG. 3, the shape of the screen 1 is formed into a spherical shape that forms a curvature R with a spherical surface, and is formed at the focal length F position formed by the curvature R of the screen 1. Configure the projectors 2 and 3 to locate.

In this case, since the relationship between the curvature R and the focal length F of the spherical surface of the screen 1 is known to be F = R / 2, F = 2R becomes a projection distance of, for example, a 100 "screen of the projector at 4.5m. If the focal length (F) is also 4.5m, the screen curvature (R) is to be 9m.

The surface reflectance (P) of the next screen (1) consists of a reflectance of 5-40%.

The reason for this is that when the surface reflectivity (P) is less than 5%, the curvature of the screen 1 is curvature, and the spherical screen 1 having a spherical surface is suitable for optical operation. More than a level of reflection is required, and for this reason, when the reflectance is less than 5%, the reflection is insignificant.

This is because when the screen reflectivity P of the screen 1 is 40% or more, the screen 1 has a strong directivity due to condensing by a spherical surface, so that the viewing angle is narrow and the contrast is strong, so that the color may collapse.

Next, the method of manufacturing the reflectivity of the surface of the screen 1 such as 5-40% is as follows.

The reflective surface can be prepared by depositing aluminum on aluminum, plastic, glass, or the like, or chromium plating the metal surface.

That is, the reflective surface of the screen 1 is different depending on the material properties, but after forming the surface particle size of 3000 mesh based on glass, and depositing reflective material such as aluminum on the surface, 100% reflective surface like mirror Formed,

In the same way, if you have a reflectance of 5% (5 gain), you will get 90-200 mesh, if you have a 40% reflectivity (40 gain), you will get 300-1000 mesh particles.

The present invention thus constructed reflects the projector 2 image projected at the focal point F position as shown in FIG. 3, regardless of the angle of incidence A, so that the viewer sees the G1 range, which is the inverse angle of the reflection range. The entire screen can be viewed evenly.

Of course, in this case, since the reflectance can be applied up to 100% (100 gain), when the screen 1 surface reflectance is lowered in the configuration shown in FIG. 3, the scattering angle (∠C) due to scattering is as much as the scattering rate. And the viewing angle is enlarged by the same scattering angle (∠C).

The field of view by the scattering angle (C) by gain (= reflectance) is inversely proportional to each other as shown in the following chart.

Therefore, as shown in FIG. 3, the viewing angle due to left and right scattering increases according to the gain number at the basic reflection angle A. FIG. That is, 5 gains are about 36 ° and 30 degrees are about 6 °.

The viewing angle may vary depending on how many percent the left and right the viewing angle is based on the right and left center of the viewing angle, but the present invention is based on the inverse reference chart for convenience of description. The projector 2, as shown in FIGS. The installation angle (D) of left and right angles of 3) should be within 10 degrees and 45 degrees.

The reason for this is that the image of the projector 2 on the left is reflected to the right and the image of the projector 3 on the right is to the left. The left and right viewing angles are enlarged by the square, and the installation angle is 10 degrees. If it is installed below, the left and right viewing angle enlargement effect is reduced and if it is more than 45 degrees, the image distortion range due to the rectangular projection is too large, so it is impossible to correct the image distortion.

The present invention as shown in Figure 4 when the projector (2, 3) to the installation angle (D) 30 degrees to the left and right with respect to the center of the screen (1) as shown in the screen (1) of the surface gain (P) 5 gain When the total viewing angle (E) is 132 °, the total viewing angle (E) is 132 ° by combining the viewing angle 36 ° by its scattering angle (∠C) and 66 degrees, which is the sum of the reflection angle 30 degrees by the installation angle (D) of the projectors (2,3). Will be.

As shown in FIG. 5, the surface reflectivity P of the screen 1 is composed of 30 gains, and three units are arranged around the left and right centers of the screen 1, but when the installation angle D of the left and right projectors 2.3 is 45 degrees, The right projector is 51 ° by adding the self-scattering angle (∠C) 6 degrees according to the chart above and the reflecting angle (∠C) 45 degrees by the installation angle (D) of the projectors (2,3). The viewing angle E is such that a wide field of view of 102 ° can be realized.

That is, as shown in FIG. 6, the left and right projectors 2 and 3 images have scattering angles (∠C) of the screen 1 and left and right projectors 2 and 3 on the left and right sides of the screen 1 in opposite directions, respectively. The total viewing angle (E) is enlarged by the sum of the reflection angle (D) by the installation angle (D).

Next, the configuration of the projector 2.3 is configured as a projector with a built-in left and right image distortion correction apparatus.

That is, the projector does not project from the central axis of the screen 1, as shown in FIG. 7, but instead of projecting from left and right angles as shown in FIG. Distortion occurs.

That is, the image angle projected from the center of the screen 1 is a right angle as shown in the "B" of FIG. 7, but since the image projected from the left and the right to the square is different from the left and right projection distance by the square, Left and right are trapezoidal shapes.

By the way, the so-called distortion correction device for correcting the distortion by sequentially increasing the scanning line 10 by increasing the upper and lower trapezoidal distortion images 7 in advance and downward as shown in FIG. 8 is known in projectors and TVs.

Therefore, the above-described vertical distortion correction device may be applied in the same logic from side to side as shown in FIG. 9 to correct the projector scanning direction.

In such a case, the left and right distortion images 7A and the right distortion images 7B of the projectors 2 and 3 projected in the left and right squares are equally corrected by left and right on the screen 1 as shown in FIG. 7AB), it is possible to combine a plurality of images as a single image.

However, even though such images coincide with each other, the reflection angles of the projection angles are different from each other, as shown in FIG.

That is, when A, B, and C each project the same image in the opposite direction of the reflection angle by the projection angle, the same image is observed, but when different images are projected, they are different depending on the viewing range of A, B, and C. It becomes the video observation.

Conventionally, when the brightness of the light source lamp is increased twice, the brightness of the general screen is increased by only 1 to 2%. That is, since the conventional screen has only 1 to 2 gains, for example, when a 100 lux projector (1) lamp is raised to 200 lux and projected onto a conventional 1 gain screen, the brightness is 1 lux is 2 lux. Although only 1% increase, when using a high brightness spherical screen of 5 to 40 gains as in the present invention, the brightness is increased by 5 to 40 times with 10 to 80 lux brightness without increasing the brightness of the light source lamp. The brightness of the projector with ANSI brightness is the same as the brightness effect when using the projector with 10,000-80,000 ANSI brightness.

Even in the left and right viewing angles, the effective left and right viewing angles of the conventional general screen do not exceed 120 degrees in view of the shortest viewing distance with respect to the horizontal size of the screen 1.

In the present invention, the total viewing angle (D) can be extended to a wide field of view from 114 ° to 144 ° by matching the angle of reflection by the rectangular arrangement of the projector and the angle of scattering by its scattering rate.

In addition, the left and right image distortion of the left and right projectors due to the rectangular projection is corrected by a known image scanning device using an electronic scanning method. Will be reflected

In addition, in the present invention, when projecting the image of the projector to each different image, it is possible to watch several different images on one screen (1).

That is, when three projectors 2, 3, and 4 project images at different projection angles on one screen 1 as shown in FIG. 6, the passersby 9 passes through positions A, B, and C as shown in FIG. In the screen (1) is able to watch a completely different image according to the viewing direction.

In other words, it is possible to view multi-images on a single screen with high brightness.

Therefore, the present invention is capable of viewing clear images even in bright daylight with a wide field of view of up to 144 ° of bright high-brightness images up to 5 to 40 times as compared to the prior art, thereby diversifying the structure within the logic of the present invention. It can be used very efficiently for advertising devices, vehicle-mounted advertising devices, sports relay video devices and auditorium video devices.

Claims (1)

In a video device that displays advertising video, etc. The structure of the screen 1 is composed of a spherical screen having a spherical surface (R) by curvature, the surface reflectance (P) is formed of 5 to 40%, The projector 2 is composed of a projector 1 equipped with a left and right image distortion correction device, At least two or more projectors 2 are disposed at a focal point F of the curvature spherical surface R of the screen 1, The interval of the projector 2 is arranged at a right angle of 10 to 45 degrees left and right with respect to the center of the screen 1, The images projected from the left and right projectors 2 to the screen 1 are reflected in left and right directions, respectively. Wide-field high-brightness imaging system characterized by realizing high brightness and wide field of view simultaneously